发布时间:
【1】 曾丹, 程义民, 等. 人眼三维肌肉控制模型. 计算机辅助设计与图形学学报.2006,18(11):1710~ 1716(EI收录)【2】 曾丹, 程义民, 等. 人眼多线谱及其获取. 电子与信息学报(EI收录)【3】 曾丹,程义民,等. 基于人眼多线谱的MPEG-4参数获取. 数据采集与处理(已录用)【4】 程义民,曾丹,等. 一种人眼运动及表情的仿真方法 . 系统仿真学报.2007,11(6): 2399~2403(EI收录)【5】 郭从良,曾丹,等. 同步辐射光源的反馈控制模型. 光学技术.2003,29(5):608~610. (EI收录)【6】 郭从良,曾丹,等. 光电倍增管的噪声模型. 核电子学与探测技术.2004,24(2);117~120
SCI收录论文(1)Shi C. H.*, J. G. Wu and P. Wu, Developmental behavior of gene expression for brown rice thickness under different environments.Genesis, 2002, 33(4):185-190.(2)Chen Z. X., J. G. Wu, W. N. Ding, H. M. Chen, P Wu andC. H. Shi*, Morphogenesis and molecular basis on naked seed rice, a novel homeoticmutation ofOsMADS1regulating transcript level ofAP3 homologue in rice.Planta, 2006, 223(5):882-890.(3)Li W. Q., J. G. Wu, S. L. Weng, Y. J. Zhang, D. P. Zhang andC. H. Shi*, RiceDwarf62(D62) encodes a novel GRAS protein modulating gibberellin signaling.Planta, 2010.(4)Shi C. H.*, J. M. Xue, Y. G. Yu, X. E. Yang and J. Zhu, Analysis of genetic effects for nutrient quality traits inindicarice.Theoretical and Applied Genetics,1996, 92(8):1099-1102.(5)Shi C. H.*, J. Zhu, R. C. Zang and G. L. Chen, Genetic and heterosis analysis for cooking quality traits ofindicarice in different environments.Theoretical and Applied Genetics, 1997, 95(1-2):294-300.(6)Li C. T.,C. H. Shi*, J. G. Wu, H. M. Xu, H. Z. Zhang and Y. L. Ren, Methods of developing core collections based on the genotypic value of rice (Oryza sativaL.).Theoretical and Applied Genetics,2004, 108(6): 1172-1176.(7)Zheng X., J. G. Wu, X. Y. Lou, H. M. XuandC. H. Shi*, The QTL analysis on maternal and endosperm genome and their environmental interactions for characters of cooking quality in rice (Oryza sativaL.).Theoretical and Applied Genetics, 2008, 116(3): 335-342.(8)Wu J. G.,C. H. Shi*,S. Y. Chen, J. F. Xiao, The cytological mechanism of low fertility in the naked seed rice.Genetica,2004, 121(3):259-267.(9)Shi C. H.*, G. K. Ge, J. G. Wu, J. Ye and P. Wu, The dynamic gene expression from different genetic systems for protein and lysine contents of indica rice.Genetica, 2006, 128(1-3):297-306.(10)Cui Y. H., J. G. Wu,C. H. Shi*, R. M. C. Littelly and R. L. Wu*, Modelling epistatic effects of embryo and endosperm QTL on seed quality traits.Genetical Research,2006, 87:61-71.(11)Wu J. G. andC. H. Shi*, Calibration model optimization for rice cooking characteristics by near infrared reflectance spectroscopy (NIRS).Food Chemistry, 2007, 103(3):1054-1061.(12)Jiang S. L., J. G. Wu, Y. Feng, X. E. Yang andC. H. Shi*, Correlation analysis of mineral element contents and quality traits in milled rice (Oryza staviaL.).Journal of Agricultural Food Chemistry,2007,55(23): 9608-9613.(13)Chen X. J., J. G. Wu,S. J. Zhou, Y. J. Yang,X. L. Ni,J. Yang,Z. J. Zhu* andC. H. Shi*,Application of near-infrared reflectance spectroscopy to evaluate the lutein and b-carotene in Chinese Kale.Journal of Food Composition and Analysis, 2009, 22(2):148-153.(14)Shi C. H.*, J. G. Wu, X. M. Zhang and P. Wu, Developmental analysis on genetic behavior of brown rice recovery inindicarice across environments.Plant Science, 2002, 163(3):555-561.(15)Zhang H. Z.,C. H. Shi*, J. G. Wu, Y. L. Ren, C. T. Li, D. Q. Zhang and Y. F. Zhang, Analysis of genetic and genotype ′ environment interaction effects from embryo, cytoplasm and maternal plant for oleic acid content ofBrassica napusL.Plant Science, 2004, 167(1): 43-48.(16)Lin J. R.,C. H. Shi*, M. G. Wu and J. G. Wu, Analysis of genetic effects for cooking quality traits ofjaponicarice across environments.Plant Science,2005, 168(6):1501-1506.(17)Shi C. H.*, J. Zhu, and J. G. Wu, Genetic and Genotype ′ Environment Interaction Effects from Embryo,Endosperm, Cytoplasm and Maternal Plant for Rice Shape Traits ofIndicaRice.Field Crops Research, 2000,68(3):191-198.(18)Shi C. H.*, J. G. Wu, X. B. Lou, J. Zhu and P. Wu, Genetic analysis of transparency and chalkiness area at different filling stages of rice (Oryza sativaL.).Field Crops Research, 2002, 76(1):1-9.(19)Wu J. G.,C. H. Shi*, X. M. Zhang and L. J. Fan, Estimating the amino acid composition in the milled rice powder by near-infrared reflectance spectroscopy.Field Crops Research, 2002, 75(1):1-7.(20)Wu J. G. andC. H. Shi*, Prediction of grain weight, brown rice weight and amylose content in single seeds of rice using near-infrared reflectance spectroscopy.Field Crops Research,2004, 87:13-21.(21)Li W. Q., J. G. Wu, S. L. Weng, D. P. Zhang, Y. J. Zhang andC. H. Shi*, Characterization and Fine Mapping of the Glabrous Leaf and Hull Mutant (gl1) in Rice (Oryza sativaL.).Plant Cell Reports, 2010, 29:617~627.(22)Wu J. G.,C. H. Shi*and H. Z. Zhang, Genetic analysis of embryo, cytoplasmic and maternal effects and their environment interactions for protein content inBrassica napusL.Australian Journal of Agriculture Research, 2005, 56(1):69-73.(23)Shi C. H.*, Y. Shi, X. Y. Lou, H. M. Xu, X. Zheng and J. G. Wu*, Identification of endosperm and maternal plant QTLs for protein and lysine contents of rice across different environments.Crop & Pasture Science, 2009, 60(3):295-301.(24)Zhang H. Z.,C. H. Shi*, J. G. Wu, Y. L. Ren, C. T. Li, D. Q. Zhang and Y. F. Zhang, Analysis of genetic effects and heritabilities for linoleic and linolenic acid content ofBrassica napusL. across environments.European J. of Lipid Science and Technology,106 (8):518-523.(25)Shi C. H.*, J. G. Wu and P. Wu, Genetic analysis of developmental behavior for amylose content in filling process of rice.Journal of the Science of Food and Agriculture,2005, 85(5):791-796.(26)Pkania C. K., J. G. Wu, H. M. Xu, C. T. Li andC. H. Shi,* Addressing rice germplasm genetic potential using genotypic value to develop quality core collections.Journal of the Science of Food and Agriculture,2007, 87:326-333.(27)Lu X. H.,L. H. Wu,L. J. Pang,Y. S. Li,J. G. Wu,C. H. Shiand F. S. Zhang, Effects of plastic film mulching cultivation under non-flooded condition on rice quality.Journal of the Science of Food and Agriculture,2007, 87:334-339.(28)Variath M. T., J. G. Wu, L. Zhang andC. H. Shi*, Analysis of developmental genetic effects from embryo, cytoplasm and maternal plant for oleic acid content and linoleic acid content of rapeseed.Journal of Agricultural Sciences,2010, 148(4):375~391.(29)Zhang X. M.,C. H. Shi*, J. G. Wu, H. Hisamitsu, T. Katsura, S. Y. Feng, G. L. Bao and S. H. Ye, Analysis of variations in the amylose content of grains located at different positions in the rice panicle and the effect of milling.Starch, 2003, 55(6):265-270.(30)Yang B. C., B. G. Xiao, X. J. Chen andC.H. Shi*,Assessing the genetic diversity of tobacco germplasm using ISSR and IRAP markers.Annals of Applied Biology,2007, 150:393-401.(31)Wu J. G.,C. H. Shi*, X. M. Z hang and T. Katsura, Genetic analysis of non-essential amino acid contents in rice (Oryza sativaL.) across environments.Hereditas, 2004, 141:128-134.(32)Jiang S. L.,C. H. Shi and J. G. Wu, Studies on mineral nutrition and safety of wild rice (OryzaL.).International Journal of Food Sciences and Nutrition, 2009, 60(1): 139-147.(33)Jiang S. L., J. G. Wu, Nguyen Ba Thang, Y. Feng, X. E. Yang andC. H. Shi*, Genotypic variation of mineral elements contents in rice (Oryza staviaL.).European Food Research and Technology,2008, 228 (1):115-122.(34)Wu J. G.,C. H. Shi*and H. Z. Zhang, Partitioning genetic effects due to embryo, cytoplasm and maternal parent for oil content in oilseed (Brassica napusL.).Genetics and Molecular Biology, 2006, 29(3):533-538.(35)Ge G. K.,C. H. Shi*, J. G. Wu and Z. H. Ye, Analysis of the genetic relationships from different genetic systems between the amylose content and the appearance quality ofindicarice across environments.Genetics and Molecular Biology, 2008, 31(3):711-716.(36)Shi C. H.*, J. Zhu, X. E. Yang, Y. G. Yu and J. G. Wu, Genetic analysis for protein content inindicarice.Euphytica, 1999, 107(2):135-140.(37)Shi C. H.*, H. Z. Zhang, J. G. Wu, C. T. Li and Y. L. Ren, Genetic and genotype ′ environment interaction effects analysis for erucic acid content in rapeseed (Brassica napusL.).Euphytica, 2003, 130(2):249-254.(38)Zhang X. M.,C. H. Shi*,S. H. Ye, J. G. Wu and G. L. Bao, Genetic analysis of methionine content inindica-japonicahybrid rice (Oryza sativaL.) at different grain developmental stages.Euphytica, 2004, 139(3):249-256.(39)Variath M. T., J. G. Wu, Y. X. Li , G. L. Chen andC. H. Shi*, Genetic analysis for oil and protein contents of rapeseed (Brassica napusL.) at different developmental times.Euphytica, 2009, 166(1):145-153.(40)Shi C. H.*,J. Zhu, J. G. Wu, X. E. Yang and Y. G. Yu., Analysis of embryo, endosperm, cytoplasmic and maternal effects for heterosis of protein and lysine content inindicahybrid rice.Plant Breeding, 1999,118(6):574-576.(41)Fan L. J., B. M. Hu,C. H. Shiand J. G. Wu, A method of choosing locations based on genotype ′ environment interaction for regional trials of rice.Plant Breeding, 2001, 120(2):139-142.(42)Guo L. B., Y. Z. Xing, H. W. Mei, C. G. Xu,C. H. Shi, P Wu and L. J. Luo, Dissection of component QTL expression in yield formation in rice.Plant Breeding,2005, 124 (2):127-132.(43)Wu J. G.,C. H. Shi*, X. M. Z hang and T. Katsura, Genetic and genotype × environment interaction effects for the content of seven essential amino acids inindicarice.Journal of Genetics, 2004, 83(2):19-24.(44)Shi C. H.*, H. Z. Zhang and J. G. Wu, Analysis of embryo, cytoplasmic and maternal correlations for quality traits of rapeseed (Brassica napusL.) across environments.Journal of Genetics, 2006, 85(2):147-151.(45)Shi C. H. *, Q. Q. Zhu, K. M Wang, G. K. Ge, J. G. Wu and Z. H. Xu*, Detecting the relationships between the amylose content and the amino acid contents ofindicarice from different genetic systems with conditional approach.Journal of Genetics, 2010, 89(1):1~8.(46)Yu G. Q., Y. Bao,C. H. Shi, C. Q. Dong and S. Ge, Genetic diversity and population differentiation of Liaoning weedy rice detected by RAPD and SSR markers.Biochemical Genetics, 2005, 43(5-6) 261-270.(47)Yang X. E., Z. Q. Ye,C. H. Shi, M. L. Zhu and R. D. Graham, Genotypic differences in concentrations of iron, manganese, copper, and zinc in polished rice grains.Journal of Plant Nutrition, 1998, 21(7):1453-1462.(48)Zhang J., M. Y. Wang, L. H. Wu, J. G. Wu andC. H. Shi, Impacts of combination of foliar iron and boron application on iron biofortification and nutritional quality of rice grain.Journal of Plant Nutrition, 2008, 31(9): 1599-161.(49)Wu J. G.,C. H. Shi*, X. M. Z hang and T. Katsura, Genetic analysis of endosperm, cytoplasmic and maternal effects for semi-essential amino acids inindicarice (Oryza sativaL.) across environments.Cereal Research Comunication, 2004, 32(4):435-442.(50)Zhang X. M.,C. H. Shi*, J. G. Wu S. H. Ye and Y. B. Qi, Analysis of developmental genetics for phenylalanine content in indica-japonica hybrid rice (Oryza sativa L.) across environments.Cereal Research Communication, 2006, 34(2):949-956.(51)Thang N. B., J. G. Wu, W. H. Zhou, W. Q. Li andC. H. Shi*, The screening of mutants and construction of mutant library forOryza sativacv. Nipponbare via ethyl methane sulphonate inducing.Biologia, 2010, 65(4):660~669(52)吴建国、石春海*和张海珍,构建整粒油菜籽脂肪酸成分近红外反射光谱分析模型的研究。光谱学与光谱分析(Spectroscopy and Spectral Analysis),2006,26(2):259~262。Wu J. G, Shi C. H and Zhang H. Z, Study on developing calibration models of fat acid composition in intact rapeseed by near infrared reflectance spectroscopy.Spectroscopy and Spectral Analysis, 2006, 26(2):259~262.(53)Shi C. H.*, J. G. Wu, L. J. Fan, J. Zhu and P. Wu, Developmental genetic analysis of brown rice weight at different environments inindicarice (Oryza sativaL.).Acta Botanica Sinica(植物学报), 2001, 43(6):603-609.(54)Shi C. H.* and J. Zhu, Genetic analysis of cytoplasmic and maternal effects for milling quality inindicarice.Seed Science and Technology.1998, 26(2):481-488.(55)Jiang S. L.,C. H. Shi*and J.G. Wu, Determination of trace amount for germanium (Ge) by atomic fluorescence spectrometry in rice (Oryza sativaL.).Journal of Food Quality, 2007, 30:481-495.(56)Shi C. H.*,J. Zhu and Y. G. Yu., Genotype × environment interaction effect and genotypic correlation for nutrient quality traits ofindicarice (Oryza sativa).Indian J. Agricultural Science, 2000, 70(2):85-89.
这应该是物理的研究范围吧,物理类的刊物是不是也可以呢,我排不了序哦,这还是要结合你的文章质量来的,物理刊物我倒是可以说一说,现代物理,应用物理都是
2、光学学报 3、发光学报 4、光子学报 5、低温物理学报6、中国激光 7、原子与分子物理学报
如果想发光电子领域的文章,可以考虑光学期刊《光电子》,是一本国际中文期刊,ISSN号为2164-5469。
可以学习ZEMAX、CODEV、TracePro、LightTools等,可以去光行天下光学专版:,学习交流一下!
光学工程 (Optical Engineering ) ,回溯至 1990 年。生物光学期刊 (Journal of Biomedical Optics) ,回溯至 1996 年。电子成像期刊 (Journal of Electronic Imaging) ,回溯至 1992 年。微印刷、微制造和微系统期刊 (Journal of Microlithography, Microfabrication, & Microsystems) , 2002 年创刊。应用遥感期刊 (Journal of Applied Remote Sensing) , 2007 年创刊。纳米光子学期刊 (Journal of Nanophotonics) , 2007 年创刊。
生物通报道:每一种新型成像技术都像是有着神奇的光环,突然一下就能看到之前不能看到的事实,近期来自华盛顿大学的研究人员发表了题为“Photoacoustic Tomography: In Vivo Imaging from Organelles to Organs”的综述文章,介绍的一种近年来迅速发展的成像技术:光声成像(photoacoustic tomography)更是如此。这一相关文章公布在Science杂志上。文章的通讯作者是华盛顿大学著名生物医学光学专家汪立宏(Lihong V. Wang)教授,汪教授现任国际生物医学光学协会主席,华中科技大学“长江学者”讲座教授。汪教授在生物医学光学成像技术方面获得了多项成果,已经出版了两本专著,在Nature Biotechnology, Physical Review Letters, Physical Review, Optics Letters, 和IEEE Transactions上发表上百篇论文。 汪教授与来自华盛顿大学医学院的医师们共同将四种光声成像技术应用到了临床,其中一种能观察到前哨淋巴结活检术(Sentinel Lymph Node),这对于乳腺癌发生阶段具有重要意义。还有一种成像技术能监控机体对化疗的早期应答,第三种技术则能成像黑色素瘤,最后一种能观察消化道。 其中最令人激动的是光声成像能揭示组织氧利用的情况,因为过量的氧燃烧(称为高代谢,hypermetabolism)是癌症的一个重要标志。汪教授说,因为癌症早期阶段,癌症还没有扩散,因此早期预警诊断无需造影剂,这将改变癌症诊断。(光声成像最令人激动的用途是检测氧代谢,氧代谢是癌症的一大标志,这将带给我们更早更有效的诊断方法。) 光声成像的原理 虽然我们已经接受了X射线成像所获得的灰色照片,但这只是我们机体内部“照片”的一个稀疏替代品。然而由于光子只能穿透约为一毫米的软体组织,之后就会散射出去,无法解析其途径,获得图形,因此我们只能接受这样的图片。 但是散射并没有破坏光子,这些基本粒子能直达7厘米的深处(大约3英寸)。光声成像的方法就在于将深处的吸收光转变成了声波,后者比光散射情况低一千倍。这可以通过某光波长纳秒脉冲激光照射成像组织来实现。 也就是说,当宽束短脉冲激光辐照生物组织时,位于组织体内的吸收体 (如肿瘤 )吸收脉冲光能量,导致升温膨胀,产生超声波。这时位于组织体表面的超声探测器件可以接收到这些外传的超声波,并依据探测到的光声信号来重建组织内光能量吸收分布的图像。 由此可见光声成像技术检测的是超声信号,反映的是光能量吸收的差异,所以这一技术能很好地结合光学和超声这两种成像技术各自的优点。而且由于探测的是超声信号,所以这一技术能克服了纯光学成像技术在成像深度与分辨率上不可兼得的不足。而且由于光声技术的图像差异来源于组织体光学吸收的不同,这就能够有效地补充纯超声成像技术在对比度和功能性方面的缺陷。 除此之外,光不同于X射线,不会产生任何健康威胁,而且光声成像也比X射线成像对比度更高,还能由“内源性”造影剂,获得彩色分子图像,这包括血红蛋白——随着获得和失去氧气,而改变颜色,还有黑色素,以及DNA——处于细胞核中的DNA比细胞质中的DNA更“暗”。 通过“外源性(引入)”造影剂的帮助,比如有机染料,或者能表达彩色分子的基因,光声成像也能对组织成像,比如淋巴结,这一结构易于周围环境混淆。汪教授还利用报告基因编码了彩色物质进行实验,这获得了良好的结果。 总体来说,光声成像这种基于生物组织内部光学吸收差异、以超声作媒介的无损生物光子成像方法,结合了纯光学成像的高对比度特性和纯超声成像的高穿透深度特性的优点,以超声探测器探测光声波代替光学成像中的光子检测,从原理上避开了光学散射的影响,可以提供高对比度和高分辨率的组织影像,为研究生物组织的结构形态、生理特征、代谢功能、病理特征等提供了重要手段,在生物医学临床诊断以及在体组织结构和功能成像领域具有广泛的应用前景。
光学工程 (Optical Engineering ) ,回溯至 1990 年。生物光学期刊 (Journal of Biomedical Optics) ,回溯至 1996 年。电子成像期刊 (Journal of Electronic Imaging) ,回溯至 1992 年。微印刷、微制造和微系统期刊 (Journal of Microlithography, Microfabrication, & Microsystems) , 2002 年创刊。应用遥感期刊 (Journal of Applied Remote Sensing) , 2007 年创刊。纳米光子学期刊 (Journal of Nanophotonics) , 2007 年创刊。
光学成像利用折射、反射等手段将物的信息再现。成像是几何光学研究的核心问题之一。实像与虚像、实物与虚物。1,物和像都是由一系列的点构成的,物点和像点一一对应。2,实物、实像的意义在于有光线实际发自或通过该点,而虚物、虚像仅仅是由光的直线传播性质给人眼造成的一种错觉,实际上并没有光线经过该点。3,物和像具有相对性,虚实之间也可以进行转换。理想成像的基本要求是满足同心光束的不变性,并且从整个物和像的对应关系看,还必须要满足物像间的相似性。空间上各个点之间的相互位置要一一对应,同时每一对物像点的颜色要一一对应。要求成像的光学系统不产生畸变,没有像差、色差等。理想光具组是严格成像的必要条件。
光学工程 (Optical Engineering ) ,回溯至 1990 年。生物光学期刊 (Journal of Biomedical Optics) ,回溯至 1996 年。电子成像期刊 (Journal of Electronic Imaging) ,回溯至 1992 年。微印刷、微制造和微系统期刊 (Journal of Microlithography, Microfabrication, & Microsystems) , 2002 年创刊。应用遥感期刊 (Journal of Applied Remote Sensing) , 2007 年创刊。纳米光子学期刊 (Journal of Nanophotonics) , 2007 年创刊。
如果想发光电子领域的文章,可以考虑光学期刊《光电子》,是一本国际中文期刊,ISSN号为2164-5469。